Control processes for a slide-scanning system comprising a carousel with a plurality of rack slots configured to receive slide racks via an exposed portion of the scanning system. In an embodiment, initializing the scanning system comprises automatically homing back-end and front-end components, wherein the front-end components comprise the carousel. An inventory of all slide racks in the carousel is automatically generated. If any slide rack was being processed by any back-end components, the slide rack is automatically unloaded into a corresponding rack slot. In addition, the carousel is automatically positioned to expose a starting subset of the rack slots within the exposed portion. This starting subset may comprise a maximum segment of adjacent empty rack slots.

The present disclosure provides apparatus and methods for handling slides. The apparatus includes a carrier comprising a retention hole and a cartridge having a case coupled to one or more separators that together define a plurality of compartments each configured to accept the carrier. At least one of the separators comprises a guide hole, with all guide holes are disposed on a first axis. The retention hole of the carrier is aligned with the first axis when the carrier is disposed in a seated position within one of the compartments. The cartridge also comprises a plurality of spacers each partially disposed within at least one of the guide holes.

A microscope system may comprise a plurality of microscope modules, a cassette for holding a plurality of slides, a slide loader configured to move the plurality of slides between the cassette and the plurality of microscope modules, and a processor coupled to the slide loader. The processor may be configured with instructions which, when executed, cause the slide loader to move a slide into or from a selected microscope module among the plurality of microscope modules. Various other methods, systems, and computer-readable media are also disclosed.

A test strip container includes: an accommodating member in which a test strip is accommodated; a moving member moving the test strip therein; a door member opening and closing at a side surface of the accommodating member to discharge the test strip out of the accommodating member, and cutting the interior and the exterior of the accommodating member off from each other when closed; a door accommodating portion covering the door member, in which the door member can open and close; and a discharge opening cutting the interior and an exterior of the door accommodating portion off from each other when closed, and is provided at the door accommodating portion so as to open and close to discharge the test strip to the exterior of the door accommodating portion, the discharge opening being able to open when the accommodating member is closed by the door member.

Devices and methods for providing and dispensing opposables onto slides are provided in which magazines loaded with opposables include retention arms to reduce movement of the opposables during shipment and processing and to reduce or eliminate contamination.

A slide rack gripper apparatus is provided that simultaneously conveys a plurality of glass slides in the protection of a slide rack within a digital slide scanning apparatus. The slide rack gripper apparatus conveys the plurality of glass slides from a slide rack carousel to a scanning stage for processing. The slide rack gripper includes a first motor attached to a base configured to drive a finger mount attached to the base along a first linear axis. The slide rack gripper apparatus also includes a second motor attached to the finger mount and configured to drive opposing gripper fingers attached to the finger mount along a second linear axis. The second motor is also configured to drive individual gripper fingers along a third linear axis to move the gripper fingers toward each other and away from each other to grasp or release a slide rack.

A device for container storing is presented. The device comprises storage with at least one storing level including a pipetting storing level for fluid pipetting. Each storing level has storing positions having a container holder to detachably hold at least one container. A handler is movable with respect to the storage for transferring containers with respect to the storing positions. A storing position of the pipetting storing level includes a flat spring to bias a container against the container holder. The flat spring has a through hole to provide a pipette access to a lid of the container. A system for pipetting is also presented, comprising the device and a pipettor movable with respect to the pipetting storing level with at least one pipette for pipetting contained in a container stored in the pipetting storing level. The pipette has a pipette tip to penetrate a lid of the container.

A device and method for delivering a laboratory sample carrier from a stack of sample carriers includes providing a retaining mechanism that retains the stack of laboratory sample carriers, and an ejector mechanism including a displaceable mechanism comprising a carrier support portion and a carrier transporting portion which are hingeably interconnected. The stack is supported by the carrier transporting portion and the carrier transporting portion is supported by a carrier transporting portion support of the ejector mechanism when the displaceable mechanism is in a first carrier receiving position and configuration. The displaceable mechanism is displaced from the first carrier receiving position and configuration to a second carrier release position and configuration by a further displacement mechanism of the ejector mechanism. This involves moving a lowermost carrier from the bottom of the stack in a carrier accommodating region of the carrier transporting portion as the displaceable mechanism is displaced from the first carrier receiving position and configuration. The displaceable mechanism is displaced such that the carrier transporting portion moves past the carrier transporting portion support and drops so that the displaceable mechanism adopts the second carrier release position and configuration and the carrier in the carrier accommodating region is released. The stack is supported with the carrier support portion when the displaceable mechanism is in the second carrier release position and configuration.

An improved quality assurance system and method for point-of-care testing are disclosed. The present invention provides quality assurance for laboratory quality tests performed by a blood analysis system or the like at the point of patient care without the need for running liquid-based quality control materials on the analysis system. Quality assurance of a quantitative physiological sample test system is performed without using a quality control sample by monitoring the thermal and temporal stress of a component used with the test system. Alert information is generated that indicates that the component has failed quality assurance when the thermal and temporal stress exceeds a predetermined thermal-temporal stress threshold. Alternatively, the present invention provides quality assurance for laboratory quality tests performed by a blood analysis system or the like at the point of patient care by minimizing the need for running liquid-based quality control materials on the analysis system.

An indexer adapted to index a test sensor from a test-sensor cartridge. The indexer includes an indexer face having a first aperture formed generally through the center thereof. The indexer further includes a retention pin extending through the first aperture and a flexible pawl positioned near an edge of the indexer face. The indexer is adapted to be rotated in a first direction and a second generally opposite direction about the retention pin. The flexible pawl is configured to bend when the indexer is rotated in the second direction. The flexible pawl is configured to assist in rotating the test-sensor cartridge.